Abstract: A catheter comprises a catheter shaft having a proximal end portion and a distal end portion, the catheter shaft defining a lumen, the lumen configured for at least one of fluid delivery and inflation, a balloon configured to be coupled to the distal end portion of the catheter shaft, wherein the balloon defines a volume in flow communication with the lumen, and a plurality of energy transfer elements disposed on a flexible circuit along at least a portion of the balloon.

Abstract: A catheter comprises an expandable spline structure defining a distal tip portion of the catheter. The spline structure comprises a plurality of individual splines, and each spline is configured to support a plurality of energy transfer elements and/or temperature sensors. An expandable balloon configured to be associated with the spline structure is unattached to the spline structure along its length.

Abstract: A medical device, system, and method having a flexible shaft and a multi-core fiber within the flexible shaft. The multi-core fiber includes a plurality of optical cores dedicated for shape sensing sensors, and a plurality of optical cores dedicated for force sensing sensors. A medical device flexing structure assembly can comprise a multi-core fiber comprising a plurality of cores, and a flexing structure comprising at least one slot. Each of the plurality of cores can comprise a fiber Bragg grating, and the flexing structure can be configured to bend in response to a force imparted on the flexing structure.

Abstract: A medical device, system, and method having a flexible shaft and a multi-core fiber within the flexible shaft. The multi-core fiber includes a plurality of optical cores dedicated for shape sensing sensors, and a plurality of optical cores dedicated for force sensing sensors. A medical device flexing structure assembly can comprise a multi-core fiber comprising a plurality of cores, and a flexing structure comprising at least one slot. Each of the plurality of cores can comprise a fiber Bragg grating, and the flexing structure can be configured to bend in response to a force imparted on the flexing structure.

Abstract: A medical device for diagnosis or treatment of tissue in a body is provided. The device includes an elongate, tubular shaft configured to be received within the body. The shaft has a proximal portion and a distal portion configured for movement relative to the proximal portion. A flexible member having a predetermined stiffness is disposed between the proximal and distal portions. A plurality of coils are disposed within the shaft with one or more of the coils configured for movement with the distal portion. Electromagnetic fields generated from within or outside of the medical device induce currents in the coils from which movement of the distal portion in response to contact of the distal portion with the tissue may be determined. In one embodiment, several of the coils are connected in series to reduce the space required in the device for conductors.

Abstract: A medical device for diagnosis or treatment of tissue in a body is provided. The device includes an elongate, tubular shaft configured to be received within the body. The shaft has a proximal portion and a distal portion configured for movement relative to the proximal portion. A flexible member having a predetermined stiffness is disposed between the proximal and distal portions. A plurality of coils are disposed within the shaft with one or more of the coils configured for movement with the distal portion. Electromagnetic fields generated from within or outside of the medical device induce currents in the coils from which movement of the distal portion in response to contact of the distal portion with the tissue may be determined. In one embodiment, several of the coils are connected in series to reduce the space required in the device for conductors.

Abstract: An ablation catheter comprises an elongated catheter body; at least one ablation element disposed in a distal portion which is adjacent the distal end of the catheter body; an illumination optical element disposed in the distal portion, the illumination optical element being light-transmissive to emit light from the illumination optical element to the targeted tissue region; and a collection optical element disposed in the distal portion, the collection optical element being light-transmissive to collect one or more of returned, backscattered or newly excited light from the targeted tissue region. The illumination or excitation optical element and the collection optical element are axially spaced from one another and axially optically isolated from one another within the distal portion to substantially prevent light from traveling between the illumination optical element and the collection optical element along a path within the distal portion.

Abstract: Electrode assemblies include segmented electrodes disposed on a catheter. The segmented electrodes can be constructed at the tip of the catheter. Tip electrodes can be constructed from an electrically insulative substrate comprising an inner lumen, an external tip surface, and a plurality of channels extending from the inner lumen to the external tip surface, a plurality of segmented electrodes, and a plurality of spot electrodes. Each of the plurality of segmented electrodes and each of the plurality of spot electrodes can be laterally separated from each other by an electrically non-conductive substrate portion and each of the spot electrodes and each of the segmented electrodes can be electrically coupled to at least one wire or conductor trace.

Abstract: A deflectable, flexible device includes an elongate body, a convoluted tip portion at a distal end of the elongate body, and a lumen to receive one or more wires. The convoluted tip portion includes an electroformed pleated region which is formed by electrodepositing a metal on a mandrel having a pleated region. The convoluted tip portion may be hermetically sealed to permit repeated sterilization. The electroformed pleated region may include one or more fluid emission orifices. The convoluted tip portion extends or bends in response to fluid pressure manipulation, contact with tissue, manipulation with an internal spring or wire, or by a user pushing, pulling, or twisting the catheter directly or via an introducer sheath or the like. The convoluted tip portion may further include an RF ablation element or other energy-driven technique to create continuous linear lesions or a sensing element.

Abstract: Medical devices for diagnosis or treatment of tissue in a body. Representative devices include an elongate shaft having a proximal portion and a distal portion configured for movement relative to the proximal portion. A flexible member having a predetermined stiffness is disposed between the proximal and distal portions. One or more coils and an electrically passive element are disposed within the shaft with either the coils or element configured for movement with the distal portion. The element comprises a material effecting an electrical characteristic of the coils. Movement of the distal portion in response to its contact with the tissue and relative movement of the coils and element causes a change in the electrical characteristic in at least one of the coils indicative of at least a contact force magnitude between the distal portion and the tissue. Several embodiments allow determination of both force magnitude and force vector direction.

Abstract: Aspects of the present disclosure relate to electrophysiology catheters for cardiac medical procedures. More specifically, the instant disclosure relates to an ablation catheter for treating cardiac arrhythmias by ablating tissue, and having one or more subelectrodes internally fixed within the ablation catheter tip to capture electrophysiology characteristics of myocardial tissue in proximity to the one or more subelectrodes.

Abstract: An ablation catheter comprises: an elongated catheter body extending longitudinally between a proximal end and a distal end along a longitudinal axis; a distal member disposed adjacent the distal end, the distal member including an ablation element to ablate a biological member; one or more acoustic transducers disposed in the distal member and each configured to direct an acoustic signal toward a respective target ablation region and receive reflection echoes therefrom; and an acoustic redirection member disposed in the distal member to at least partially redirect the acoustic signal from at least one of the acoustic transducers toward a tissue target. The distal member includes a most-distal portion, a proximal portion, and a deflectable portion between the most-distal portion and proximal portion to permit deflection between the most-distal portion and proximal portion of the distal member. The transducers and redirection member are mounted on opposite sides of the deflectable portion.

Abstract: Electrode assemblies include segmented electrodes disposed on a catheter. The segmented electrodes can be constructed at the tip of the catheter. Tip electrodes can be constructed from an electrically insulative substrate comprising an inner lumen, an external tip surface, and a plurality of channels extending from the inner lumen to the external tip surface, a plurality of segmented electrodes, and a plurality of spot electrodes. Each of the plurality of segmented electrodes and each of the plurality of spot electrodes can be laterally separated from each other by an electrically non-conductive substrate portion and each of the spot electrodes and each of the segmented electrodes can be electrically coupled to at least one wire or conductor trace.

Abstract: An ablation catheter comprises an elongated catheter body; at least one ablation element disposed in a distal portion which is adjacent the distal end of the catheter body; an illumination optical element disposed in the distal portion, the illumination optical element being light-transmissive to emit light from the illumination optical element to the targeted tissue region; and a collection optical element disposed in the distal portion, the collection optical element being light-transmissive to collect one or more of returned, backscattered or newly excited light from the targeted tissue region. The illumination or excitation optical element and the collection optical element are axially spaced from one another and axially optically isolated from one another within the distal portion to substantially prevent light from traveling between the illumination optical element and the collection optical element along a path within the distal portion.

Abstract: A deflectable, flexible device includes an elongate body, a convoluted tip portion at a distal end of the elongate body, and a lumen to receive one or more wires. The convoluted tip portion includes an electroformed pleated region which is formed by electrodepositing a metal on a mandrel having a pleated region. The convoluted tip portion may be hermetically sealed to permit repeated sterilization. The electroformed pleated region may include one or more fluid emission orifices. The convoluted tip portion extends or bends in response to fluid pressure manipulation, contact with tissue, manipulation with an internal spring or wire, or by a user pushing, pulling, or twisting the catheter directly or via an introducer sheath or the like. The convoluted tip portion may further include an RF ablation element or other energy-driven technique to create continuous linear lesions or a sensing element.

Abstract: An ablation catheter comprises: an elongated catheter body extending longitudinally between a proximal end and a distal end along a longitudinal axis; a distal member disposed adjacent the distal end, the distal member including an ablation element to ablate a biological member; one or more acoustic transducers disposed in the distal member and each configured to direct an acoustic signal toward a respective target ablation region and receive reflection echoes therefrom; and an acoustic redirection member disposed in the distal member to at least partially redirect the acoustic signal from at least one of the acoustic transducers toward a tissue target. The distal member includes a most-distal portion, a proximal portion, and a deflectable portion between the most-distal portion and proximal portion to permit deflection between the most-distal portion and proximal portion of the distal member. The transducers and redirection member are mounted on opposite sides of the deflectable portion.

Abstract: A catheter comprises an expandable spline structure defining a distal tip portion of the catheter. The spline structure comprises a plurality of individual splines, and each spline is configured to support a plurality of energy transfer elements and/or temperature sensors. An expandable balloon configured to be associated with the spline structure is unattached to the spline structure along its length.

Abstract: Devices and methods for creating radial-linear lesions in pulmonary vein antral tissue are disclosed. In an embodiment, a device includes an elongate shaft structure with a distal tip ablation region including a spline and an ablation element slidably coupled to the spline. The ablation element includes at least one of an ultrasound emitter, a high frequency ultrasound emitter, a laser, a radiofrequency electrode, a virtual radiofrequency electrode, or a cryogenic source. A backing balloon may be configured to push or pull the spline and the ablation element toward or against the pulmonary vein antral tissue. In an embodiment, the distal tip ablation region includes a splineless cryoballoon with at least one thermally conductive region.

Abstract: A force-sensing tip assembly for a catheter comprises a tip shell, an acoustic transducer, a first target, and a first spring. The tip shell is for joining to the catheter. The acoustic transducer is disposed within the tip shell and is capable of generating an acoustic ping. The first target is spaced from the acoustic transducer within the tip shell. The first spring is in the tip shell and configured to allow a relative position between the acoustic transducer and the first target to change over a range. The first target is shaped and positioned to reflect at least a portion of the acoustic ping back to the acoustic transducer as a first echo over at least a portion of the range.

Abstract: A tip for a medical device includes a hollow body having a window, a sensor positioned within the hollow body and oriented such that its active surface is pointed towards the window, and a membrane positioned within a beam path of the sensor. The membrane passes energy without preventing an outer surface of the hollow body of the tip from coming in contact with tissue, thus allowing the hollow body to deliver therapy to an adjacent tissue and/or diagnose adjacent tissue. The membrane can cover the window or the sensor. The membrane is desirably permeable to an irrigant, such that a suitable level of irrigant outflow from the window is maintained, and thin enough that it minimizes attenuation of energy passing to and/or from the sensor.